IntroductionBiofilms are defined as microbial derived sessile communities which attach themselves to solid surfaces or to each other by using their sticky appendages and employing a rolling motion. So they could show continuous attachments to the surface and forming micro aggregation (Taj et al., 2012). Previous investigations have shown that biofilms are resistant to antimicrobial agents (Mohammad and Shalakany, 2015). Bacteria growing in a biofilm are 1000 fold resistant than planktonic cells to antibiotics. Therefore, higher concentrations of antibiotics are needed to inactivate bacteria grown on a biofilm (Hassan et al., 2011).Antimicrobial agents have a significant role in decreasing the percentage of infectious diseases in both animals andhumans (Tadesse et al., 2012). However the constant use of antimicrobials over a period of time is one of the important reasons leading to prevalence of antibiotic-resistant bacteria (Van den Bogaard et al., 2001). The most significant factor for the development of antibiotic resistance is the exposure of different antibiotics with different concentrations into the microflora of human and animal guts. Over a period of time under the selective pressure, resistant bacteria will have overgrowth (Sayah et al., 2005). In veterinary medicine, antimicrobial agents are commonly used as growth promoter which leads to the high resistance toward antibiotics in normal and pathogenic bacterial flora of poultry (Romanus et al., 2012). Since resistant bacteria from food animals may colonize the humans through the food chain, contact via occupational exposure or waste run off from animal production facilities, it is possible that antibiotic-resistant bacteria could be transferred from food animals to man (Schroeder et al., 2002).E. coli is known for its ability to cause different types of infections. Among them, gastrointestinal infections leading to the diarrhea are important. Additionally, a variety of diseases outside of the gut of humans and animals such as urinary tract infections, sepsis, meningitis, abdominal infections, osteomyelitis, cellulitis, wound infections and colibacillosis are significant (Kazemnia et al., 2014). E. coli colibacillosis usually causes the considerable damages to poultry production all around the world (Rafiei Tabatabaei and Nasirian, 2003). Surveillance data indicated that E. coli have strong ability for biofilm formation and emergence of resistance in E. coli is one of the highest for antimicrobial agents that have been in use the longest time in human and animals (Tadesse et al., 2012).In this study, E. coli strains isolated from chicken and human clinical samples were analyzed to determine their biofilm producing properties and their susceptibilities to antimicrobial agents.Materials and MethodsBacterial strainsA total of 100 strains of E. coli from humans and chicken samples; including 50 samples from human urine and 50 samples from chicken muscles, were isolated from September to December 2013 from Urmia, Iran.BacteriologyAll samples were macroscopically and microscopically examined by gram staining (Abdul Rahaman Shariff et al., 2013). Then cultured on MacConkey and Eosin methylene blue agar plates (Sigma Aldrich, USA) and incubated at 37oC for 24h. The colonies suspected to be E. coli were identified by other bacteriological assays (Hammerum and Heuer, 2009).All human and chicken isolates were frozen in Nutrient broth containing 30% glycerol at -70oC until further processing (Tadesse et al., 2012).Molecular identification of E. coliAll human and avian E. coli isolates were sub cultured overnight in Nutrient broth media (Sigma Aldrich, USA) and genomic DNA was extracted using bacterial genomic DNA purification kit (Intron, Korea). Then the presence of E. coli 16s rRNA gene was determined by polymerase chain reaction (PCR) method using forward primer:5'-GTATAGATACCCTGGTAGTCCA-3' and reverse primer:5'-CCCGGGAACGTATTCACCG-3' (Sharma et al., 2013). The PCR assay was done in a total volume of 25 μl using Intron premix (Korea). The PCR was performed in a DNA thermo cycler (MWG AG Biotech Thermal Cycler, USA) and the PCR conditions were as follow: an initial template denaturation at 95oC for 3 mins, 26 cycles followed with DNA denaturation at 94oC for 1 min, annealing at 55oC for 1 min and extension at 72oC for 10 mins (Sharma et al., 2013). The PCR products were separated electrophoretically in 1% agarose gel.Detection of biofilm formationBiofilm formation by E. coli isolates was assayed by microtitre plate, tube and cover slip assays. In microtitre plate assay 1×107 cfu of E. coli in 100 microliter LB Broth medium was inoculated into the wells of 96 well flat bottom polystyrene plates (Sigma Aldrich, USA). After growing bacteria at 37oC for 48h, the planktonic cells in media were discarded. The plate was washed and the attached biofilms were stained with 0.1% crystal violet (20 min). After rinsing the plates with distilled water, all stains associated with the attached biofilms were dissolved with 95% ethanol and OD595 absorbance was measured (Nakao et al., 2009). An optical density of 0.240 was chosen to distinguish biofilm producers from non-biofilm formers (Van den Bogaard et al., 2001).In the tube method, a loop full of bacteria was cultured in 10 ml trypticase soy broth with 1% glucose. After incubation at 37oC for 24h, tubes were decanted and washed with phosphate buffer saline. Then tubes were stained with 0.1% crystal violet stain. Each tube was then gently rotated to ensure uniform staining and then the contents were gently decanted. The tubes were placed upside down to dry. Biofilm formation was considered positive when a visible film lined the wall and the bottom of the tube (Hassan et al., 2011).In coverslip method, sterile culture flasks were filled with 50 ml Brain heart infusion broth media and 18mm glass microscope cover slip added to it. Then defined volume of overnight culture of bacteria was inoculated into the flasks. After incubating the flasks at 37oC for 48h, glass cover slip containing biofilm was removed and rinsed with phosphate buffer saline then stained with 0.5% crystal violet stain for 5min. Stained biofilms were then microscopically screened (Sharma et al., 2013).Antimicrobial drug susceptibility testingWhile a single E. coli isolated and identified from each collected sample, the antimicrobial susceptibility tests were done on Muller-Hinton agar plates using Kirby Bauer disk diffusion method. A 150mm Muller- Hinton medium plate was swabbed with Nutrient broth inoculated with E. coli, and incubated to a turbidity of 0.5 McFarland standard medium. Twelve prepared antimicrobial agent disks were place on the inoculated plate. Then these plates were incubated at 35oC for 18 to 20h. The diameter zone of growth inhibition around each disk was measured (Sayah et al., 2005). Selected disks for this study were: Tetracycline(30 μg), Ceftriaxone(30 μg), Doxycycline(30 μg), Amikacin(30μg), Cefixime(5 mcg), Gentamicin(10μg), Furazolidone(100 mcg), Amikacin(30μg), Ceftazidime(30-μg), Cefotaxime(30 μg), Nalidixicacid(30μg), Nitrofurantoin(300 mcg), Ciprofloxacin(5μg) (Padtan Teb, Iran). The diameters of the zones of inhibition were interpreted by referring to the Performance Standard for Antimicrobial Susceptibility Testing; Twenty-Third Informational Supplement – January 2013.ResultsBacteria detectionAll 100 isolated bacteria from human and avian samples had the cultural, morphological and biochemical characteristics of E. coli (Fig. 1). Moreover, molecular identification of E. coli 16s rRNA gene using PCR method confirmed the E. coli isolates. Fig. 2 shows the product of 16s rRNA gene found at 612bp using 100bp DNA marker.

Biofilm formationAmong 50 human E. coli isolates, microtitre plate method detected 72% as biofilm producers, which followed by tube test (66%) and cover slip assay (56%). Thirty two percent of human E. coli strains were confirmed to have biofilm forming ability by all three methods. Thirty four percent were positive biofilm producers by two assays. Thirty two percent were detected as biofilm producers by only one method. Two percent of isolates did not have any ability in biofilm formation.Among 50 avian E. coli isolates, microtitre plate method detected 38% biofilm producers which followed by tube test (60%) and cover slip assay (54%). Eighteen percent of human E. coli strains were confirmed to have biofilm forming ability by all three methods. Fifty four percent were positive biofilm producer by two assays and 28% were detected as biofilm producers by only one method.Two percent of isolates did not have any ability in biofilm formation (Fig. 3, 4, 5).